System and method for remotely executing an interpretive language application

ABSTRACT

A server node in a client-server system downloads and executes application written in interpretive languages on behalf of associated client nodes. A connection manager provides communications control in a server of a client-server system. The connection manager permits the client node to establish rudimentary communications with a designated server port and then moves the connection to a communications port specific to the application running on the server. The specific communications port is then configured by the communications manager with the protocol drivers required by the client node. The server node then executes an application written in an interpretive language on behalf of the client node. The server accepts input from the client node, allowing client processor to interact with the downloaded application. Output from the downloaded application is transmitted to the client node, which displays the output normally.

FIELD OF THE INVENTION

The present invention relates to execution of applications in a distributed client-server environment and, in particular, to the remote execution of applications written in interpretive languages in a client-server environment.

BACKGROUND OF THE INVENTION

The worldwide network of computers commonly known as the "Internet" has seen explosive growth in the last several years. Much of this growth has been driven by the increase in popularity of the World Wide Web (WWW). The WWW is a collection of files written using HyperText Markup Language (HTML), commonly referred to as "Web pages." HTML files may be accessed and displayed using specialized applications known as "web" browsers, which allow a user to access HTML files using a simple graphical user interface (GUI).

Servers hosting HTML files can communicate using the Hypertext Transfer Protocol (HTTP). HTTP is an application protocol that provides users access to files (which can be in different formats such as text, graphics, images, sound, video, etc.) using the HTML page description language. HTML provides basic document formatting and allows the developer to specify communication "links" to other servers and files. Use of an HTML-compliant client browser involves specification of a link via a Uniform Resource Locator or "URL." Upon such specification, the client makes a TCP/IP request to the server identified in the link and receives a "Web page" in return. Further, organizations can provide HTML files that are accessible from within the organization but not from the WWW. These internal networks and collections of HTML files are commonly referred to as "Intranets."

A file written using HTML includes "tags," which indicate to a browser displaying the file when special action should be taken. For example, a tag may indicate to the browser: (1) that a graphics file should be displayed at a particular point in the document; (2) that certain text should centered, bolded, or otherwise formatted; (3) that the background of a document should be shaded or have a particular pattern; or (4) that a different HTML should be loaded in place of the HTML the browser is currently displaying.

One major drawback of HTML files, however, is that they are inherently static. That is, HTML is a "display only" language, which does not easily permit execution of applications within an HTML page. Companies seeking to leverage the popularity and ubiquity of the WWW are increasingly looking for ways to embed applications within an HTML file.

One attempt to allow HTML files to provide an execution environment for applications is the use of interpretive languages, sometimes known as "byte code" languages, typified by the JAVA programming language. A JAVA program, usually called an applet, is completely downloaded to the client before executing. This may be problematic for clients lacking sufficient memory to download the entire applet and, even if the client has enough memory, requires the client to wait for the applet to download. Similarly, the usual benefits achieved in a client-server environment are reduced because the JAVA applet is downloaded to and executed on the client, which typically has a lower bandwidth connection and a slower processing speed than a server.

SUMMARY OF THE INVENTION

The present invention relates to a method for remotely executing interpretive languages in a client-server environment. The server to which a client is connected downloads and executes an application written in an interpretive language, such as a JAVA applet. The server accepts input from, and provides screen data to, the client. This allows the client to appear as if it is executing the application in a traditional manner without requiring the client to expend compute and memory resources hosting and executing the application. Additionally, the server may be able to download the application more quickly than the client. The server also accepts input from the client node, allowing the client node to control and provide input to the downloaded application.

In one aspect, the present invention relates to a method for remotely executing an application written in an interpretive language which begins by downloading the application to a server node in response to a request made by a client node. A connection is established between the client node and a predetermined communications port located on the server; the server creates an endpoint data structure and associates a client space hosted by the server with the endpoint data structure. The server generates a protocol stack associated with the client space and the associated endpoint data structure, notifies a connection manager of the connection, and transfers the connection between the predetermined communications port and the client node to the associated protocol stack.

In another aspect, the invention relates to an article of manufacture having computer-readable program means embodied thereon for remotely executing an application written in an interpretive language. The article of manufacture includes: computer-readable program means for downloading the application to a server node in response to a request made by a client node; computer-readable program means for establishing a connection between the client node and a predetermined communications port located on the server; computer-readable program means for creating an endpoint data structure; computer-readable program means for associating a client space hosted by the server with the endpoint data structure; computer-readable program means for generating a protocol stack associated with the client space and the associated endpoint data structure; computer-readable program means for notifying a connection manager of the connection; and computer-readable program means for transferring the connection between the predetermined communications port and the client node to the associated protocol stack.

In still another aspect, the present invention relates to a system for remotely executing an application written in an interpretive language. The system includes a server node having a predetermined communications port and a client node having a communications device establishing a connection between the client node and the predetermined communications port of the server node. A protocol stack is located on the server node and the protocol stack includes an endpoint data structure. A client space located in memory on the server node is associated with the protocol stack and provides an execution environment for an application written in an interpretive language. The system further includes a communication manager located on the server node, and a notification device located on the server node. The notification device notifying the connection manager of the connection between the client node and the predetermined communications port and the communications manager transferring the connection between the predetermined communications port and the client node to the protocol stack.

BRIEF DESCRIPTION OF THE DRAWINGS

This invention is pointed out with particularity in the appended claims. The advantages of this invention described above, as well as further advantages, may be better understood by referring to the following description taken in conjunction with the accompanying drawings, in which:

FIG. 1 is a highly schematic diagram of an embodiment of a communication system utilizing the invention;

FIG. 2 is a block diagram of an embodiment of the invention showing the connections between various components of the server of FIG. 1 which occur during communication between the clients and server;

FIG. 3 is a block diagram of an embodiment of the invention that maintains and manages multiple client node connections;

FIG. 4 is a block diagram of an embodiment of the system for embedding applications in an HTML page;

FIG. 5 is a diagrammatic view of a client node;

FIG. 6 is a block diagram of an embodiment of the invention depicting the use of a multiplexer to transmit the same data from an application to more than one client; and

FIG. 7 is a block diagram of the embodiment of the invention in which the broadcast capabilities are increased by fan out.

DETAILED DESCRIPTION OF THE INVENTION

Referring now to FIG. 1, in brief overview, a typical network 20 includes at least one client node 24, at least one server node 34, 34', and a master network information node 40 connected together by a communications link 44. The embodiment shown in FIG. 1 depicts the communications link 44 as a local area network ring or LAN ring, but any communication topology may be used. For the purpose of explanation the server node 34 is assumed to have the application 30 requested by the client node 24. Also, for the purpose of explanation, the master network information node 40 is assumed to be a distinct server node, but in actuality the master network information node 40 may be an application execution server node 34. It should be noted that on a given LAN several nodes may be capable of acting as a network information node, but at any one time only one of such nodes is designated the master network information node 40 for the system and it is to this node that client requests for server information are directed.

The master network information node 40 maintains a table of addresses for the application execution server nodes 34, 34'. In addition, the master network information node 40 receives messages from each application execution server node 34, 34' indicating its level of activity. The level of activity of the application execution server nodes 34, 34' is maintained in a table along with the address of each of the application execution server nodes 34 and is used by the communications system 44 for load leveling.

When the client 24 wishes to have an application executed on an application execution server node 34, the client node 24 sends a request to the general communications port previously defined by the communications protocol or to the "well-known" communications port on the master network information node 40. In one embodiment the communication takes place by way of a datagram service. The master network information node 40 accesses the table of server addresses and returns a message containing the address of the application execution server or application server 34 which has the requested application and also which has the least load. Subsequent communications are automatically addressed by the client also to a "well-known" or predefined general communications port on the server node 34. In one embodiment, the type of protocol with which the initial query was made to the master network information node 40 determines the protocol of the information returned by the master network information node 40 to the client node 24. Thus if the request were made using a TCP/IP datagram, the master network information node 40 would return the TCP/IP address of the server 34 to the client node 24 and the client node 24 would subsequently establish contact with the server node 34 using that protocol. In another embodiment, the datagram requesting an application address by a client 24 includes a request for a different type of protocol than the one used to send the request to the master network information node 40. For example, the client 24 may make a request to the master network information node 40 using the IPX protocol and request the address of the application server as a TCP/IP protocol address.

When a client node 24 (actually a client process 56 on a client node 24) desires to communicate with an application on a server node 34, 34' the client node 24 begins by issuing a network request to determine the location of the server 34 having the desired application. This request is received by the master network information node 40 (also referred to as a network browser 40) residing somewhere on the network. In this FIG. 1, the network browser 40 is shown for simplicity as residing on a different server 40 from the server which has the application, but such may generally not be the case.

The network master information node 40 returns the network address of the server node 34 having the desired application to the client node 24. The client node 24 then uses the information received from the network master information node 40 to request connection to the application executing on the specified server 34. As is described above, such a connection is first established to a "well-known" communications port and is later transferred to a specific communications port under control of a connection manager. The specific communications port is associated with the application executing on the server node 34 which then communicates with the client node 24 through the specific communications port.

In more detail, and referring to FIG. 2, the client process 56 on client node 24 makes a request 54 to the network master information node 40 to obtain the address of a server node 34 which includes the desired application 62. The network master information node 40 returns to the client node 24 a message 58 containing the address of the server node 34 which includes the server application 62. In one embodiment, the protocol used at this point of the connection is a datagram service.

The client node 24 uses the returned address to establish a communication channel 68 with the server 34. The port number used by the client 24 corresponds to the "well-known port" in the server 34 which has been defined by the network protocol as the port by which the server 34 establishes communication connections with clients 24. The well-known port 72 has a rudimentary protocol stack 76 which includes primarily an endpoint data structure 78.

The endpoint data structure 78 points to the communication protocol stack 76 and client connection thereby establishing a unique representation or "handle" for the client 24. The endpoint data structure 78 permits the connection between the server 34 and the client 24 to be moved at will between the connection manager 80 and the various applications 62 on the server 34. The endpoint data structure 78, in one embodiment, not only contains the handle to the client 24 but may also contain other information relating to the client connection. In the embodiment shown, the application server 34 monitors activity on a specific communications system (e.g. LAN or WAN) and has initialized this minimum protocol stack 76 with only the necessary protocol modules needed to support a "TTY" communication mode. The "TTY" communication mode is a simple ASCII stream with no protocol assumptions above the transport layer. That is, there are no protocol layers for compression, encryption, reliability, framing, or presentation of transmitted data. Thus a client node 24 seeking an application 62 running on the server 34 establishes a connection to the well-known communications port 72 with the minimum protocol set needed to support a TTY communication mode.

A connection manager 80 executing on the server node 34 is "listening" to the well-known communications port 72 for a connection request 68. When a connection request 68 is received from the client node 24, the connection manager 80 is notified 84. The connection manager 80 knows which protocol is being used based on the notification 84.

With this information the connection manager 80 creates a new minimum protocol communications stack 104, starts the execution environment 96 and binds the new minimum protocol stack 104 to the execution environment 96. In one embodiment, the server 34 includes a number of execution environments 96 which have been previously been started, but which have not been associated with a communications port. In this embodiment, the pre-connection starting of the execution environments permits a faster response time than if each execution environment 96 is started when the connection request is received from the client 24. When the execution environment 96 is started, the server application 62 requested by the client 24 is also started. In another embodiment, if the client 24 does not specify an application, either a default application is started or simply the execution environment 96 with no application is started.

The connection manager 80 then moves the client connection, including the unique client identifier or handle, from the well-known port 76 to the new minimum protocol stack 104. The connection manager 80, using the minimum protocol stack 104 sends a TTY data stream that indicates service is available. Thus, this method for detecting a client connection is independent of the port to which the connection is first established. If the client node 24 does not respond within a prescribed time period (e.g. 5 seconds) to the service available message, a resend of the "service available" message is performed by the server 34.

If the client 24 receives the message, the client 24 sends a TTY string indicating that the "service available" message was detected. The client 24 waits for the server 34 to respond and if the response is not within a prescribed time interval (e.g. 5 seconds) the client 24 resends the message. The connection manager 80 then queries 90 the client 24 asking for the client's default communication parameters. This query 90 takes the form of a message which is passed back to the client 24 and which indicates that the client 24 should respond with details regarding what protocols the client 24 would like to use in the connection.

In response, the client 24 sends a set of protocol packets 92; each packet of which is used to specify a required or optional protocol module that is being requested from the server 34. In one embodiment, the number of packets in the set is variable with one packet being sent for each protocol requested. In another embodiment, the number of packets that is being sent is included in the header of the first packet. In a third embodiment, the remaining number of packets being sent is included in the header of each packet and is decremented with each succeeding packet sent. Thus, the client 24 may respond to the query 90 by indicating that, for example, encryption and data compression will be used. In such a case, two protocol packets will be sent from the client 24 to the server 34 and, in one embodiment, the header of the first packet will indicate the number of packets as two.

Once the responses to the query 90 have been received, the connection manager 80 builds a protocol stack using protocol drivers 120, 120', 120" which correspond to the protocols requested by the client node 24. In one embodiment, the connection manager 80 places each of the required protocol drivers 120, 120', 120", corresponding to the requested client protocols (e.g. an encryption driver if encryption is desired by the client) into the protocol stack "container" 112 and links them together. This dynamic process allows a client node 24 to specify the contents of a protocol stack dynamically without requiring that the server 34 have a prior protocol stack description for a particular client node 24. Using this method, multiple clients 24 may be served by a single server, even if the separate clients 24 have vastly differing requirements for the associated connection channel. In the embodiment shown, each client 24, 24', 24" is associated with a respective connection protocol stack 104, 104' and 104". Such dynamically extensible protocol stacks are described in more detail below and in U.S. patent application Ser. No. 08/540,891, filed on Oct. 11, 1995 and incorporated herein by reference.

In the embodiment just discussed, the "container" 112 is a user level or kernel level device driver, such as an NT device driver. This container driver provides ancillary support for the inner protocol modules or "drivers" (generally 120) which correspond to the protocol requirements of the client node 24. This ancillary support is in the form of helper routines that, for example, aid one protocol driver to transfer data to the next driver. Alternatively, in another embodiment each protocol driver is a complete user-level or kernel-level driver in itself.

Referring now to the embodiment depicted in FIG. 3, the connection manager 80 includes two main software modules: ICASRV.EXE 90 and ICAAPI.DLL 94. In the embodiment shown, ICASRV.EXE 90 is the server side of a client/server interface. ICASRV.EXE 90 manages all connection states and is, in one embodiment, implemented as a WINDOWS NT™ service. A second part of the connection manager 80 is ICAAPI.DLL 94. ICAAPI.DLL 94 establishes the connection with the client, establishes the protocols to be used and notifies ICASRV.EXE 90 of the completion of the protocol stack. In one embodiment, a third module CDMODEM.DLL 96 is linked to ICAAPI.DLL 94'. CDMODEM.DLL 96 is a module which ICAAPI.DLL 94' uses to communicate with modem devices.

The connection methodology described above can be used for a client 24 running a Web browser program. For the purposes of this specification, the user running the Web browser program will be referred to as the "viewing user." The terms "server" or "server node" will be used to refer to machines hosting HTML files or applications that may be executed. For example, a viewing user runs a Web browser on a client node and makes file requests via the HTTP protocol to servers. The servers respond by transmitting file data to the client via the HTTP protocol. The Web browser run on the client receives the transmitted data and displays the data as an HTML page to the viewing user.

In brief overview and referring to FIG. 4, an HTML file 64 located on a server 34' and constructed in accordance with an embodiment of the invention includes a generic embedded window tag 66. The generic embedded window tag 66 is any data construct which indicates to a browser 60 displaying the HTML file 64 that a generic embedded window 66' should be displayed at a particular location in the HTML page 64' described by the HTML file 64. The generic embedded window tag 66 may include additional information, such as height of the window, width of the window, border style of the window, background color or pattern in the window, which applications may be displayed in the window, how often the output display should be updated, or any other additional information that is useful to enhance display of the application output.

Some examples of generic embedded window tags that can be embedded in an HTML file follow.

    ______________________________________     ActiveX tag     <object classid="clsid:238f6f83-b8b4-11cf-8771-00a024541ee3"     data="/ica/direct.ica" CODEBASE="/cab/wfica.cab"     width=436 height=295>     <param name="Start" value="Auto">- <param name="Border" value="On">     </object>     Netscape Plugin tag     <embed src="http://www.citrix.com/ica/direct.ica"     pluginspage="http://www.citrix.com/plugi.html"     height=295 width=436 Start=Auto Border=On>     <embed>     JAVA tag     <applet code=JICA.class width=436 height=295>     <param name=Address  value="128.4.1.64">     <param name=InitialProgram                          value=Microsoft Word 7.0>     <param name=Start    value=Auto>     <param name=Border   value=On>     <applet>     ______________________________________

In each case above, the tag indicates that a window having a height of 295 pixels and a width of 436 pixels should be drawn to receive application output. Each tag also specifies that the application should automatically start execution and that the window in which the application output is displayed should be drawn with a border. The ActiveX and Netscape Plugin tags have the remote application parameters specified in the file "direct.ica" located in the directory "/ica." The JAVA tag specifies the remote application parameters directly. In the example above, the address of the server hosting the application is specified as well as the name of the application to be executed.

The browser application 60 accesses the HTML file 64 by issuing a request to a specific Uniform Resource Locator (URL) address. The server 34' hosting the HTML file 64 transmits the HTML file 64 data to the browser application 60, which displays text and translates any tags that are included in the HTML file 64. The browser application 60 displays the HTML file 64 data as an HTML page 64'. If a generic embedded window tag 66 is present in the HTML file 64, such as one of the tags described above, the browser 60 draws a blank window 66' in the displayed HTML page 64'.

Execution of the desired application 62' may commence immediately upon display of the HTML page 64' or execution may await some signal, e.g. a specified user input which indicates execution of the application 62' should begin. Once execution of the application 62' is commenced, the browser application 60 instantiates a parameter handler 40 associated with the application window 66'. The parameter handler 40 instance may be spawned as a child process of the browser application 60, as a peer process of the browser application 60, or as a Dynamically Linked Library ("DLL") associated with the browser application 60.

The browser application 60 passes any specific parameters associated with the application window 66' that were provided by the generic embedded window 66 tag to the parameter handler 40 instance. Additionally, the browser application 60 may pass the handle for the application window 66' to the parameter handler 40 instance or the parameter handler 40 instance may query the browser application 60 to retrieve the handle for the application window 66'. The parameter handler 40 instance also spawns a network executive 50. The network executive 50 may be spawned as a child process of the parameter handler 40 instance or as a peer process of the parameter handler 40 instance.

The parameter handler 40 instance forwards any specified application window 66' parameters to the network executive 50. Parameters which are not specified by the parameter handler 40 instance or the embedded generic window tag 66 may be set to default values. The network executive 50 may have certain parameter defaults hard-coded, or the network executive 50 may access a file which contains parameter defaults.

The network executive 50 creates its own application output window 66". The network executive 50 creates its application output window 66" as a child of the displayed application window 66' and displays its application output window 66" directly over the parent window 66' drawn by the browser application 60. Since the application output window 66" drawn by the network executive 50 is a child of the application window 66' drawn by the browser application 60, the application output window 66" inherits various properties of its parent including position information. Accordingly, the application output window 66" will follow the application window 66' as the viewing user scrolls the screen of the browser application 60 or performs other actions which vary the position of the application window 66'.

The network executive 50 also establishes a connection channel with the server 34 and invokes execution of the desired application 62' by the server 34" using the connection methodology described above. The network executive 50, which acts as the client in the above description, passes any parameters it received from the parameter handler 40 instantiation to the server, along with any necessary default values. If a parameter is not passed to the server, the server may request the parameter if it is a necessary parameter which has no default value, e.g. "user id," or it may provide a default value for the parameter, e.g. execution priority. The server 34" begins execution of the desired application program 62' and directs the output to the network executive 50. The network executive 50 receives data from the application program 62' and displays the output data in its application output window 66". Since the application output window 66" is drawn on top of the application window 66' drawn by the browser application 60, the application output data is displayed in the HTML page 64'. As noted above, the application output window 66" drawn by the network executive 50 is a child of the application window 66' drawn by the browser application 60. This allows the application output window 66" to scroll as the HTML page 64' is scrolled.

The application output window 66" also receives input from the viewing user. Raw input data, e.g. a mouse click, is received into the application output window 66" by the network executive 50. The network executive 50 forwards the raw input data to the application 62' executing on the server 34". In this manner, the viewing user is able to interact with the application 62' via the HTML page 64'.

Referring now to FIG. 5, the viewing user uses a so-called "browser" program to display an HTML page 64' having an application window 66' on the screen 18 of the user's computer 14. The viewing user may invoke execution of an application program 62'. Typically this is done by the user utilizing a "point-and-click" interface, i.e. the viewing user uses a mouse 16 to manipulate a cursor 12 that is also displayed on the screen 18 of the viewing user's computer 14. Once the cursor 12 is over a particular portion of the HTML page 64', the viewing user signals by "clicking" a button 15 on the mouse 16. Alternatively, the viewing user may also signal by pressing a key on an associated keyboard 17, such as the "return" key. In other embodiments, the viewing user may not use a mouse 16 at all, but may instead use a touchpad, a trackball, a pressure-sensitive tablet and pen, or some other input mechanism for manipulating the cursor 12.

In another embodiment, the application window 66', or another portion of the HTML page 64', may define a "hot zone." When the viewing user moves the cursor 12 into the "hot zone," execution of the application 62' on the server 34" is started.

Once the viewing user has indicated that execution of the application 62' should commence, the browser application 60 instantiates a parameter handler 40 and passes the instantiation parameters associated with the applications window 66' by the generic embedded window tag 66. The parameter handler 40 instance spawns a network executive 50 and passes to it the parameters of the application window 66'. The network executive 50 determines which application 62' is to be invoked, and on what server 34" that application 62' resides. Generally this information is passed to it by the parameter handler 40 instance which gets it from the browser application 60 in the form of the generic embedded window tag 66, but the network executive 50 may need to query a master network information node 40 or other various servers, in order to determine which servers, if any, host the desired application 62'. The network executive 50 then begins execution of the application and displays the output of the application program 62' in the applications window 66' as described in detail above.

The network executive 50 continues to directly display application output in the applications output window 66" until the viewing user indicates that execution of the application 62' should stop, e.g. by closing the application window 66', or until the viewing user clicks on a tag indicating that a different HTML page should be displayed. When this occurs, execution of the application 62' can be terminated. It is preferred, however, is to "cache" the connection. In effect, the first parameter handler 40 instance is not immediately terminated. However, the application 62' continues executing with a reduced priority level, i.e. in "background" mode, because the first parameter handles 40 no longer has "focus".

In general, it is desirable to accomplish connection caching by providing the parameter handler 40 source code with a globally accessible data structure for registering instances. For example, the parameter handler 40 may be provided with a globally accessible linked list data structure, data array, data table, or other data structure. Because the data structure is globally available, each instance of the parameter handler 40 is able to read and write the data structure. This allows each instance of the parameter handler 40 to "register" with every other instance by writing to the data structure to signal its existence.

For embodiments in which no other connection information is stored, a predetermined limit on the number of connections that may be cached at any one time can be set. In these embodiments if registration of an instance would result in an excess number of cached connections, one of the "cached" connections is removed, i.e. the parameter handler 40 instantiation associated with that connection is notified that it should terminate. Before termination, the parameter handler 40 notifies its associated network executive 50 that it should terminate. In turn, the network executive 50 closes its session with the server hosting the application program 62' and then terminates.

In embodiments in which other information is stored, the additional information may be used to more effectively manage the cached connections. For example, if a user has not actively viewed an HTML page 64' in a predetermined number of minutes, e.g. ten minutes, the parameter handler 40 instantiation is instructed to terminate, the session with the hosting server is terminated, and the parameter handler 40 instance removes its entry in the registry.

Cached connection information may be managed using any known cache management scheme. Connection entries may be discarded on a "first in, first out" basis, i.e. the oldest entry is discarded each time a new entry must be added. Alternatively, cached connection information entries may be discarded on a "least recently used" basis, which discards information relating to connections which have been used the least amount by the user. Other cache management techniques, such as random replacement, may also be used.

If the viewing user returns to a previous HTML page 64' having a cached connection, the network executive 50 associated with the HTML page 64' is returned to the foreground, i.e., it regains "focus", and processing of the associated application resumes at a normal priority level. If necessary, the network executive 50 re-establishes the connection with the application 62'. Although no output data is stored by the network executive 50 for cached connections, as soon as a connection is re-established for an applications window 66' the connection to the application 62' is re-established and the application 62' again writes directly to the applications window 66'.

Similarly, the connection methodology described above may be used to provide remote execution of an application written in an interpretive language. Referring once again to FIG. 2, a client node 24 is connected to a server node 34 which executes an application 62 on behalf of the client node 24. In this example, the server application 62 is any application which allows the client node 24 to request an application written in an interpretive language. For example, the application 62 may be a Web browser which allows the client node 24 to download JAVA applications using URL addresses. As just described, the node from which the application is downloaded and the server node 34 are separate machines interconnected by a computer network. However, in some embodiments those machines may be one and the same.

In order to avoid requiring the client node 24 to store and execute the downloaded application, which can be prohibitive both in terms of client memory and processor usage, the execution environment 96 on the server node 34 with which the client node 24 is associated provides an execution environment for the downloaded application. The execution environment interprets the byte stream of the downloaded application to produce a series of commands representing the application. If the application is written in the JAVA interpretive language, the execution environment is sometimes referred to as a "virtual JAVA machine".

In some embodiments the execution environment includes a compiler. These compilers convert the byte stream of the application into "native" code. For example, a compiler may convert the byte stream of an application written in the JAVA application language into 80486 machine code. Conversion of the interpretive language byte stream into native code allows the application to execute faster than if each byte must interpreted and executed at run-time. Some compilers, however, may compile the byte stream while the application is executing. These compilers are sometimes referred to as "just in time" compilers, and usually look a predetermined number of bytes ahead of the currently-executing instruction executing in order to produce a steady stream of compiled code.

The downloaded application is interpreted and executed by the server node 24 and the output of the application is transmitted to the client node as described in connection with FIG. 2. The server node 34 also accepts input from the client node 24. This allows the client node 24 to control the downloaded application or provide input to the application. The server node 34 may set up a separate execution environment to interpret and execute the downloaded application. In these embodiments, the execution environment associated with the downloaded application would also direct its output to mux 121.

Referring to FIG. 6, it should be noted that any client 24, 24', 24", or in fact, all the clients (generally 24) attached to server 34 with the application 63 may be another server 34', 34". In this manner, data transmitted by the application 63 is sent to other servers prior to being sent to client nodes 24. In this manner, data transmitted by the application 63 is transmitted to an ever increasing number of client nodes as this network fans out.

When each client 24 terminates its connection with the server 34, each client protocol stack (generally 104) and its associated minimal stack (generally 107) is destroyed. Similarly, the minimal protocol stack (generally 106) associated with the first client protocol stack 104 is also destroyed. When the last of the minimal 107 and second (and subsequent) client protocol stacks 104 has terminated, the configuration is as it was initially with only a first client connection protocol stack 104 associated with the execution environment 96. Note that until all the second and subsequent client protocol stacks 104 are terminated, the first client protocol stack 104 may not be destroyed, even if the first client 24 is no longer present.

As shown in FIG. 2, each execution environment 96 communicates with each protocol stack 104 through a multiplexer 121, 121', 121". Now referring also to FIG. 6, with the present invention it is possible for more than one client to receive data being transmitted to the first client 24, for example, in order to shadow or monitor the transmission of data from a server 34 or to broadcast data from a specialized broadcast application, such as a stock quotation application, from which the same data is broadcast or transmitted substantially simultaneously to a number of clients (generally 24).

In such a case, the first client 24 causes the specialized application 63 to execute and transmit its data to the client 24 as discussed previously. When a second client 24' requests access to the broadcast application 63, the connection manager 80 begins to construct the protocol stack 104' for the second client 24' as previously discussed with regard to the first client 24. However, because the application 63 is a broadcast application, the connection manager 80 recognizes that it need not start an additional execution environment 96 and instead takes the steps necessary to send the data from the broadcast application 63 to the second client 24' and any additional clients 24".

First, the connection manager 80 creates a first minimal connection protocol stack 106 which it associates with a connection protocol stack 104 of the first client 24. The connection manager 80 next creates a second minimal protocol stack 107 and associates it with the connection protocol stack 104' of the second client 24'. As each additional client 24" requests access to the broadcast application 63, another minimal protocol stack 106' is created and associated with the first client protocol stack 104 and another minimal protocol stack 107' and client protocol stack 104" is created for each new client 24". The first client protocol stack 104 and all the minimal protocol stacks 106, 106' associated with the first client protocol stack 104, and each pair of client protocol stacks 104', 104" and minimal protocol stacks 107, 107' associated with each additional client 24', 24" are in communication by way of a multiplexer 121.

When multiplexer 121 is directing data to or receiving data from only one client 24, the multiplexer 121 is acting as a simple pass-through device. However, when there is more than one client 24, 24', 24" receiving data from or transmitting data to a single application 63, each multiplexer (generally 121) takes on two additional configurations. In one configuration, the multiplexer 121' is configured to send application data to or receive data from both the first client protocol stack 104 and each of the minimal connection protocol stacks 106, 106' associated with it. In the second configuration the multiplexer 121" is configured to send data received by the minimal protocol stack 107, 107' to the client protocol stack 104', 104", respectively, associated with it. In this embodiment, the mux 121 may receive input data directly from each client protocol stack 104, 104', 104".

The connection manager 80 connects the minimal protocol stacks 106, 106' associated with the first client 24 with the minimal protocol stacks 107, 107' respectively, of the second 24' and subsequent clients 24" and instructs the multiplexer 121 to direct output from the application 63 to the connection protocol stack 104 of the first client 24 and its associated minimal protocol stacks 106, 106'. The multiplexer 121 is also instructed by the connection manager 80 to connect each second and subsequent client minimal protocol stack 107, 107' to its associated client protocol stack 104, 104', respectively. Data transmitted to the first client 24 by way of the first client protocol stack 104 is therefore also transmitted to the minimal protocol stacks 106, 106' associated with the first client 24 and hence to the second 24' and subsequent clients 24" by way of their associated protocol stacks 104', 104", respectively, and associated minimal protocol stacks 107, 107', respectively. In one embodiment, the protocol stack container includes a data structure to keep track of the number and type of protocols associated with a given application 63.

Referring to FIG. 7, as discussed above, it is possible that the "clients" of one server 34 be other servers 34' and 34" (only two being shown for simplicity). The second servers 34' and 34" then transmit the data to clients (generally 24) or to additional servers. In this embodiment the output of the server protocol stack (generally 104) is connected to the protocol stacks 107' of the secondary servers 34', 34". Then as described previously, the data is transmitted between the protocol stacks and out to the clients (generally 24). In this manner the data may fan out and be distributed to many more clients than may reasonably be supported by one server.

While the invention has been particularly shown and described with reference to specific preferred embodiments, it should be understood by those skilled in the art that various changes in form and detail may be made therein departing from the spirit and scope of the invention as defined by the appended claims. 

What is claimed is:
 1. A method for remotely executing an application written in an interpretive language, the method comprising the steps of:(a) downloading an application to a server node in response to a request made by a client node to execute the application; (b) establishing a connection with the client node and a predetermined communications port located on the server node using an initial protocol stack; (c) generating a data structure representing the connection and associated with the initial protocol stack; (d) generating a client space in the server node; (e) generating a second protocol stack associated with the client space; (f) notifying a connection manager of the connection to the client node; and (g) transferring the connection between the server node and the client node from the initial protocol stack to the second protocol stack by associating the data structure with the second protocol stack.
 2. The method of claim 1 wherein step (b) further comprises:(b-a) receiving by a master network information node an application request from said client node; (b-b) providing by the master network information node to the client node a server address and the predetermined port address to the server having the downloaded application; and (b-c) receiving, by the server a request from the client node to connect to the predetermined connection port based on the provided addresses.
 3. The method of claim 1 wherein step (d) further comprises associating a virtual machine providing an execution environment on the server node.
 4. The method of claim 1 wherein step (d) comprises associating a virtual JAVA machine providing an execution environment on the server node.
 5. The method of claim 1 further comprising the step of accepting input from the client node.
 6. An article of manufacture having computer-readable program means embodied thereon for remotely executing an application written in an interpretive language, the article of manufacture comprising:computer-readable program means for downloading an application to a server node in response to a request made by a client node to execute the application; computer-readable program means for establishing a connection between the client node and a predetermined communications port located on the server node using an initial protocol stack; computer-readable program means for creating a data structure representing the connection and associated with the initial protocol stack; computer-readable program means for associating the client node with a client space hosted by the server node; computer-readable program means for generating a second protocol stack associated with the client space; computer-readable program means for notifying a connection manager of the connection; and computer-readable program means for transferring the connection between the predetermined communications port and the client node from the initial protocol stack to the associated second protocol stack by associating the data structure with the second protocol stack.
 7. The article of manufacture of claim 6 further comprising:computer-readable program means for receiving an application request from the client node; computer-readable program means for providing a server address to the client node; and computer-readable program means for receiving a request from the client node to connect to the predetermined port based on the provided addresses.
 8. The article of manufacture of claim 6 further comprising:computer-readable program means for associating a virtual machine providing an execution environment with said data structure.
 9. The article of manufacture of claim 6 further comprising:computer-readable program means for issuing a protocol query to the client node; computer-readable program means for generating the second protocol stack based on the response of the client node to the protocol query.
 10. The article of manufacture of claim 6 further comprising: computer-readable program means for receiving input from the client node.
 11. A system for remotely executing an application written in an interpretive language, the system comprising:a server node having a predetermined communications port; a client node having a communications device establishing a connection between said client node and said predetermined communications port of said server node using an initial protocol stack associated with a data structure representing the connection; a second protocol stack located on said server node; a client space located in memory on said server node, said client space associated with said second protocol stack and providing a dynamic compilation environment for an application written in an interpretive language; a connection manager located on said server node; and a notification device located on said server node, said notification device notifying said connection manager of said connection between said client node and said predetermined communications port, said connection manager transferring said connection between the predetermined communications port and said client node from the initial protocol stack to said second protocol stack by associating the data structure with the second protocol stack.
 12. The system of claim 11 further comprising a multiplexer in communication with each of a plurality of protocol stacks.
 13. The system of claim 11 wherein said multiplexer comprises a linked list of protocol stacks and each protocol stack maintains a connection with a client node.
 14. The system of claim 11 wherein each protocol stack is configured to allow drivers to be pushed onto that protocol stack.
 15. A method for remotely executing an application written in an interpretive language, the method comprising the steps of:receiving a request from a client node to execute an application written in an interpretive language; establishing, in response to the request, a connection between the client node and a server node using an initial protocol stack having an associated data structure representing the connection; generating a second protocol stack associated with an execution environment on the server node; associating the execution environment with the application written in an interpretive language; transferring the connection from the initial protocol stack to the second protocol stack by associating the data structure with the second protocol stack; and executing the application written in an interpretive language on the server node.
 16. The method of claim 15 further comprising the step of transmitting information produced by executing the application to the client node using the second protocol stack.
 17. The method of claim 15 further comprising the step of downloading the application written in an interpretive language to the server node from another node.
 18. The method of claim 15 further comprising the steps of receiving input from the client node to be used by the application executing on the server node. 